Complexity in chemistry biology and ecology

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Complexity in chemistry biology and ecology

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Complexity in Chemistry, Biology, and Ecology MATHEMATICAL AND COMPUTATIONAL CHEMISTRY Series Editor: PAUL G MEZEY University of Saskatchewan Saskatoon, Saskatchewan FUNDAMENTALS OF MOLECULAR SIMILARITY Edited by Ramon Carb´o-Dorca, Xavier Giron´es, and Paul G Mezey MANY-ELECTRON DENSITIES AND REDUCED DENSITY MATRICES Edited by Jerzy Cioslowski SIMPLE THEOREMS, PROOFS, AND DERIVATIONS IN QUANTUM CHEMISTRY Istv´an Mayer COMPLEXITY IN CHEMISTRY, BIOLOGY, AND ECOLOGY Danail Bonchev and Dennis H Rouvray A Continuation Order Plan is available for this series A continuation order will bring delivery of each new volume immediately upon publication Volumes are billed only upon actual shipment For further information please contact the publisher Complexity in Chemistry, Biology, and Ecology Edited by Danail Bonchev Virginia Commonwealth University Richmond, Virginia and Dennis H Rouvray University of Georgia Athens, Georgia Library of Congress Control Number: 2005925502 ISBN-10: 0-387-23264-8 ISBN-13: 978-0387-23264-5 eISBN: 0-387-25871-X Printed on acid-free paper C 2005 Springer Science+Business Media, Inc All rights reserved This work may not be translated or copied in whole or in part without the written permission of the publisher (Springer Science+Business Media, Inc., 233 Spring Street, New York, NY 10013, USA), except for brief excerpts in connection with reviews or scholarly analysis Use in connection with any form of information storage and retrieval, electronic adaptation, computer software, or by similar or dissimilar methodology now known or hereafter developed is forbidden The use in this publication of trade names, trademarks, service marks, and similar terms, even if they are not identified as such, is not to be taken as an expression of opinion as to whether or not they are subject to proprietary rights Printed in the United States of America springeronline.com (TB/EB) CONTRIBUTORS Alexandru T Balaban, Texas A & M University at Galveston, Galveston, Texas Danail Bonchev, Center for the Study of Biological Complexity, Virginia Commonwealth University, Richmond, Virginia Gregory A Buck, Center for the Study of Biological Complexity, Virginia Commonwealth University, Richmond, Virginia Pau Fernández, ICREA-Complex Systems Laboratory, Universitat Pompeu Fabra (GRIB), Barcelona, Spain Gabor Forgacs, University of Missouri, Columbia, Missouri Xiaofeng Guo, Department of Mathematics, Xiamen University, P R China Lemont B Kier, Center for the Study of Biological Complexity, Virginia Commonwealth University, Richmond, Virginia Donald C Mikulecky, Center for the Study of Biological Complexity, Virginia Commonwealth University, Richmond, Virginia Stuart A Newman, New York Medical College, Valhalla, New York Dejan Plavˇsi´c, Institute Rudjer Boˇskovi´c, Zagreb, Croatia Milan Randi´c, National Institute of Chemistry, Ljubljana, Slovenia v vi Contributors Ricard V Sol´e, ICREA-Complex Systems Lab, Universitat Pompeu Fabra (GRIB), Barcelona, Spain Robert E Ulanowicz, University of Maryland, Center for Environmental Science, Chesapeake Biological Laboratory Tarynn M Witten, Center for the Study of Biological Complexity, Virginia Commonwealth University, Richmond, Virginia PREFACE As we were at pains to point out in the companion volume to this monograph, entitled Complexity in Chemistry: Introduction and Fundamentals, complexity is to be encountered just about everywhere All that is needed for us to see it is a suitably trained eye and it then appears almost magically in all manner of guises Because of its ubiquity, complexity has been and currently still is being defined in a number of different ways Some of these definitions have led us to major and powerful new insights Thus, even in the present monograph, the important distinction is drawn between the interpretations of the concepts of complexity and complication and this is shown to have a significant bearing on how systems are modeled Having said this, however, we should not fail to mention that the broad consensus that now gained acceptance is that all of the definitions of complexity are in the last analysis to be understood in essentially intuitive terms Such definitions will therefore always have a certain degree of fuzziness associated with them But this latter desideratum should in no way be viewed as diminishing the great usefulness of the concept in any of the many scientific disciplines to which it can be applied In the chapters that are included in this monograph the fact that differing concepts of complexity can be utilized in a variety of disciplines is made explicit The specific disciplines that we embrace herein are chemistry, biochemistry, biology, and ecology Chapter 1, “On the Complexity of Fullerenes and Nanotubes,” is written by an international team of scientists led by Milan Randi´c While devoted to specific chemical applications of complexity theory, and dealing vii viii Preface with hot topics in contemporary chemical technology, the chapter complements contributions to the quantification of complexity made in the preceding volume Complexity in Chemistry Most approaches to the notion of complexity in molecules and molecular graphs have been based on an evaluation of selected graph invariants, calculated for the graph itself or, most recently, for all of its subgraphs This chapter focuses more on the influence that symmetry elements have on complexity of the objects considered This is a controversial theme, with opposing opinions in the literature, because of the prevailing view on symmetry as a simplifying factor The authors offer an improvement of symmetry-based complexity measures by accounting for the cardinality of the sets of equivalent elements In addition, the concept of presenting the complexity measure as a complexity vector or sequence, originally developed for subgraph-based complexity measures, is now realized for distance-based sequences The latter contain the average count of the number of nearest neighbors at various distances, and in the case of the fullerenes also the average distance between the twelve pentagonal faces of the fullerenes The review ends with a discussion of the complexity of nanotubes, for which the main role appears to be played by the twist and counter-twist parameters that determine the nanotube helicity and diameter As in the case of the fullerenes, the authors conclude that no single parameter seems to be sufficient to characterize nanotube complexity In Chapter 2, Newman and Forgacs focus on the physicochemical aspects of complexity in developmental and evolutionary biology The major emphasis in development studies has traditionally been on the hierarchical regulatory relationships among genes, while the variation of genes has played a corresponding role in evolutionary research Recently, however, investigators have focused on the roles played by the physical and dynamical properties of cells and tissues in producing biological characteristics during ontogeny and phylogeny The interactions among gene products, metabolites, ions, etc., reaction-diffusion coupling, and opportunities for molecular diffusion over macroscopic distances, lead to self-organizing multistable, oscillatory, and pattern forming dynamics These system properties, not specified in any genetic program, can account for most of the features of animal body structures, including cell differentiation, tissue multilayering, segmentation, and left-right asymmetry The authors point out that these chemical-dynamic properties are generic and are common to living and nonliving systems As such, they have played a major role in the evolution Preface ix of ancestral multicellular organisms, more than for modern organisms with their hierarchical genetic control The morphologies originally generated by physicochemical dynamics probably provided morphological templates for genetic evolution that stabilized and reinforced (rather than innovated) multicellular body plans and organ forms The hierarchical genetic control of development seen in modern organisms can thus be considered as an outcome of this evolutionary interplay between genetic change and generic physicochemical processes The chapter “The Circle That Never Ends: Can Complexity Be Made Simple?” by Mikulecky begins with the premise that all real systems are complex and that there can be no single approach to such systems Mikulecky presents an introduction to a relatively new approach called “relational systems theory” to which he has made valuable contributions along with such pioneers as Katchalsky, Peusner, and Rosen As an essential part of the efforts being made to create a new, non-Newtonian paradigm of science, this theory accounts for the irreducibility of certain context dependent functional components in the system, components that would disappear when the context defining them is destroyed by reductionist techniques The influence of reductionism on the methods of science is described by Mikulecky in some detail in an effort to provide reasons for moving beyond the restrictions to systems imposed on us by this traditional approach The relational approach clearly identifies the nature of the functional components as that entity which makes a complex whole more than the sum of its parts The relational model is expressed in terms of processes rather than its physical parts There is no way to uniquely identify a functional component by the way it relates to the physical parts of the system even though a relationship has to exist Relational models that are context dependent and self-referential are considered inherently incapable of being reduced to the algorithmic procedures that make mechanistic systems so adaptable to computer simulation and other computational techniques This non-computability, which makes it impossible to explain fully a system proceeding from a single model, is thus regarded as a key characteristic of complex reality The study of the organization extant in mechanisms holds out the promise of bridging the gap between the mechanistic approach characteristic of reductionism and the new relational approach For that reason, Mikulecky makes use of Network Thermodynamics to illustrate the relation between organization and the material parts in mechanisms as a way of showing AUTHOR INDEX Abraham, R., 117, 118 Adam, G., 284 Ajayan, P M., 38 Albert, R., 170, 181, 221, 229, 253 Alberts, B., 164 Aldana, M., 186, 187 Aldana-Gonz´alez, M., 182 Allen, M P., 246, 247 Allen, T F H., 251, 317 Altenberg, L., 166 Ancel, L W., 166 Anderson, P W., 239 Andriotis, A N., 43 Arbib, M., 118 Artavanis-Tsakonas, S., 67 Asai, R., 71 Auslander, D M., 115 Ayers, F., Hr., Aylsworth, A S., 76 Babic, D., Bak, P., 324 Balaban, A T., 4, 7, 37, 41, 43 Barab´asi, A L., 170, 221, 226, 253 Barone, R., Barwise, J., 102 Bar-Yam, Y., 251 Bateson, W., 65, 90 Beckenbach, E F., 29 Belew, R K., 250 Bellairs, R., 67 Bellman, R., 29 Ben-Jacob, E., 89 Bertalanffy, L V., 89 Bertz, S H., 1, 27, 192, 207, 208 Beveridge, D L., 239 Bhalla, U S., 256 Biro, L P., 43 Blackwell, W A., 115 Boissonade, J., 79 Bollob´as, B., 158 Boltzmann, L., 320 Bonchev, D., 1, 2, 11, 191, 192, 198, 203, 204, 205, 207, 208, 209, 210, 211, 219, 225, 229, 230, 253, 290 Borisuk, M T., 53 Boyarsky, L L., 307 Branford, W W., 76 Branin, H., Jr., 118, 126 Breedveldt, P C., 115 Broadie, K., 184 Brooks, D., 304 Brown, S J., 80 Bytautas, L., 27 331 332 Cable, M B., 116 Calenbuhr, V., 239 Callen, B., 121, 135 Campos-Ortega, J A., 67 Caplan, S R., 121, 136, 143 Castets, V., 76 Casti, J L., 303 Chanon, M., Chen, Y., 76 Cheng, C K., 274, 275, 281, 291 Christen, B., 70 Chua, L O., 114, 123, 129, 130, 133 Clements, D., 74 Cluzel, P., 186 Clyde, D E., 80 Cohen, J E., 303 Cohen, S M., 70 Combs, A., 239 Comper, W D., 89 Cooke, J., 66, 90 Cooke, K L., 240, 252 Cornish-Bowden, A., 85 Cotton, F A., 36, 37 Crespi, V H., 43 Cruziat, P., 116 Curran, P F., 98, 121 Cvetkovi´c, D M., Davidson, E H., 253 Dawes, R., 80 DeAngelis, D L., 311 Decker, P., 255 Defay, R., 121 Degn, H., 255 deGroot, S R., 121, 143 Delbruck, M., 284 Dennett, D C., 326 Depew, D J., 325 DeRusso, P M., 129 DeSimone, A., 143 Desoer, C A., 115 Devillers, J., Diudea, M V., 43 Dorogovtsev, S N., 170, 221, 226 Author Index Dress, W., 98 Dresselhaus, M S., 43 Dubrulle, J., 65, 66 Dunlap, B I., 43 Dunne, J A., 226, 228, 230 Ebbesen, T W., 38 Eckmann, J.-P., 253 Eigen, M., 285, 311 El-Basil, S., 27 Elowitz, M B., 53 Elsasser, W M., 308 Engleberg, J., 307 Entchev, E V., 70 Epstein, I R., 79 Espadaler, J., 165 Essig, A., 121, 136 Featherstone, D E., 184 Feher, J J., 116 Fell, D A., 221 Ferell, J E., 290, 296 Fidelman, M L., 116, 140 Figueras, J., Fitts, 121 Fontana, W., 166 Forgacs, G., 89 Frasch, M., 79 Friedman, N., 221 Frisch, H L., 71 Gavin, A C., 221, 222, 223, 224, 226 Ge, M H., 37, 43 Gebben, V D., 115 Gehring, W J., 83 Gell-Mann, M., 202 Gerhart, J., 74 Giancotti, F G., 59 Gilbert, S F., 49, 51, 65, 70 Giot, L., 221 Goerner, S., 303 Goldstein, L J., 116 Goodwin, B C., 54, 89 Gordeeva, K., 192 Author Index Gordon, M., 208 Green, J., 70 Gurdon, J B., 59, 64, 90 Gutfreund, H., 239 Gutin, A M., 165 Gutman, I., 1, 5, 6, 211 Haile, J M., 246, 247 Haken, H., 311 Hamada, H., 76 Harary, F., 193, 198 Harding, K., 83 Harland, R., 74 Harrison, L J., 84 Hatsapoulos, G N., 121 Hentschel, H G E., 71 Herndon, W C., 208 Hess, B., 255 Ho, R K., 67 Hoffman, D D., 102 Hoffman, R., Holley, S A., 67 Holling, C S., 324 Hollon, T., 53 Horgan, J., 101, 103, 114, 138 Horno, J C., 116 Howard, K., 79 Howell, J R., 116 Huang, C Y F., 290, 296 Huf, E G., 116 Ihara, S., 43 Ijima, S., 38 Ingham, P., 79 Irvine, K D., 79 Ish-Horowicz, D., 83 Ito, T., 171, 173, 221 Itow, T., 77 Iyengar, R., 256 Jablonka, E., 54 Jaszczak, J A., 43 Jeong, H., 221 Jiang, T., 71 333 Joergensen, S E., 306 John, P E., Jorgensen, W L., 239, 246, 247 Juan, H., 76 Kamenska, V., 192 Kaneko, K., 60, 62, 64, 67, 91 Karabunarliev, S., 225 Karamata, J., 28 Karnopp, D., 115, 118 Karr, T L., 79 Kastler, H., 191 Katchalsky, A., 98, 121, 132, 141 Kauffman S., 311 Kauffman, S A., 54, 181, 182 Kay, J., 303 Kay, J J., 98 Kedem, O., 132, 136, 141 Keenan, J H., 121 Keller, A D., 55, 56, 57, 67, 85, 90, 91 Kercel, S W., 147 Kerszberg, M., 70 Kier, L B., 256, 274, 275, 277, 278, 280, 281, 284, 289, 290, 291 Kilian, J., 43 Kirby, E C., 43 Kirchhoff, R., 127 Klein, D J., 5, 27, 37, 38 Koch, C., 221 Koenig, H E., 115 Kolmogorov, A N., 191 Kondo, S., 71 Kostoff, R N., 38 Krăatschmer, W., 38 Kroto, H W., 38 Kurusawa, C., 60, 62 Laidboeur, T., 20, 24, 34 Lam, Y., 130 Lamb, M J., 54 Lammert, P E., 43 Lander, A D., 70 Laurent, G., 221 Lawrence, P A., 77, 79 334 Lawton, J H., 322 Leach, A R., 246 Lee, T I., 221 Leibler, S., 53 Lengyel, I., 79 Lercher, M J., 53 Levin, S A., 239 Levine, H., 89 Levine, M., 79 Lewin, R., 305 Lewis, J., 67, 69, 90 Li, S., 171 Lin, P., 129, 133 Linshitz, H., 191 Liu, J., 43 Lovasz, L., Lukovits, I., 43 Ma, H., 221 MacDonald, N., 252 MacFarlane, G J., 115 Madan, R N., 114, 130 Manes, E G., 118 Mangold, H., 71 Mannervik, M., 55 Margolus, N., 257 Marsden, J E., 118 Maslov, M., 172 Maslov, S., 172, 229 Mason, S J., 132 Maturana, H R., 112, 146, 311 May, J M., 116 May, R M., 322 Mazur, P., 121, 143 McDowell, N., 70 McIrvine, E C., 319 Meinhardt, H., 71, 72, 74, 75, 84, 89, 90 Meir, E., 90 Mejer, H., 306 Mendes, J F F., 170, 221 Merz, K M., Jr., 37 Mierson, S., 116 Mikhailov, A S., 239 Author Index Mikulecky, D C., 99, 101, 103, 114, 115, 116, 119, 122, 130, 133, 134, 136, 138, 140, 146, 147, 153, 303 Miller, D G., 137 Milo, R., 253 Minarik, E M., 303 Minoli, D., 191 Mintz, E., 116 Mitchell, M., 250 Monk, N A., 67, 90 Montoya, J M., 253 Morgan, H L., 4, 17, 197 Morisco, C., 59 Moss, L., 102 Mowshowitz, A., 2, 191 Muirhead, R F., 25 Măuller, G B., 54, 77, 89, 91 Muratov, C B., 79 National Science Foundation, 245 Neixner, J., 115 Neuman, M E J., 199, 200 Newman, M E J., 159, 172 Newman, S A., 54, 71, 76, 77, 83, 89, 91 Nicoli´c, N., 205, 211 Nicolis, G., 255 Nieuwkoop, P D., 70 Nijhout, H F., 71 Nikolic, S., 1, 7, 15, 192 Noether, A., 305 Nonaka, S., 76 Norden, J S., 322 Noyes, R M., 255 Nusslein-Volhard, C., 79 Oates, A C., 67 Odum, E P., 321 Oken, D E., 116 Olsen, L F., 255 Onsager, L., 131, 136 Oster, G F., 98, 115, 118, 120, 122, 126 Othmer, H G., 181 Ouyang, Q., 76 Author Index Palmeirim, I., 65, 66, 90 Patel, N H., 77, 80 Pelikan, J., Penfield, P., Jr., 120 Perelson, S., 115, 118 Peusner, L., 98, 115, 116, 119, 136 Pimm, S L., 322 Platt, J R., 207 Plavˇsi´c, D., 1, 20, 30, 205 Plesser, T., 255 Polansky, O E., 2, 11, 192 Popper, K., 98 Popper, K R., 309 Pourqui´e, O., 65, 66, 84 Prideaux, J., 116 Prigogine, I., 121, 255, 325 Primas, H., 1, Primmett, D R., 67 Randi´c, M., 1, 3, 4, 5, 6, 7, 8, 20, 27, 28, 30, 205 Rashevsky, N., 89, 103, 191, 252 Ravasz, E., 166, 253 Razinger, M., 4, 17 Reinitz, J., 85, 91 Renfrew, C., 240, 252 Rideout, V C., 115 Roe, P H., 115 Rosen, R., 98, 99, 101, 103, 121, 126, 138, 143, 252, 303, 306, 317 Rosenburg, R C., 115, 118 Rouvray, D H., 205 Ruch, E., 5, Răucker, C., 1, 4, 192, 209, 211, 212 Răucker, G., 1, 4, 192, 209, 211, 212 Ruoslahti, E., 59 Rypins, E B., 116 Sakuma, R., 76 Salazar-Cuidad, I., 78, 81, 82, 83, 84, 85, 86, 87, 88, 91 Salthe, S N., 251, 303, 317, 325 Satorras-Pastor, R., 253 Sattler, K., 37, 43 335 Sauer, F A., 115 Savageau, M A., 239 Scantleburry, G R., 208 Schier, A F., 76, 83 Schmalhausen, I I., 83 Schneider, E D., 98, 303 Schroeder, M., 257 Schulte-Merker, S., 74 Scuseria, G E., 43 Segel, L A., 239 Seither, R L., 116, 134 Seitz, W A., 192, 208, 211, 230 Selkov, E E., 255 Shannon, C., 2, 191 Sharma, K R., 255 Shaw, C D., 117 Slack, J., 70 Small, S., 80, 81 Smith, J C., 74 Sneppen, K., 172, 229 Sol´e, R V., 155, 166, 175, 177, 181, 253 Solnica-Krezel, L., 72, 76 Sommer, T J., 192, 230 Spemann, H., 71 St Johnston, D., 79 Stadler, N M., 166 Standley, H J., 59 Starr, T B., 251, 317 Stengers, I, 325 Stent, G., 304 Stern, C D., 67 Stevens, C F., 305 Stollewerk, A., 79 Strand, R., 303 Strogatz, S H., 52, 53, 54, 163, 213 Strohman, R C., 305 Sulis, W., 239 Sun, B., 73 Swinney, H., 76 Takke, C., 67 Talley, D B., 116 Teleman, A A., 70 Tellegen, D H., 120 336 Author Index Terrones, M., 43 Testa, B., 256 Thakker, K M., 116, 134 Thellier, M., 116 Thoma, J U., 115 Thomas, R., 116 Thomas, S R., 128, 133 Tildesley, D J., 246 Tirado-Rives, J., 247 Tisza, L., 121 Toffoli, T., 257 Tong, A H Y., 185, 221 Townend, M S., 239 Treacy, M M J., 43 Tribus, M., 319 Trinajsti´c, N., 192, 193, 203, 209, 210, 211 Trucco, E., 191 Truesdell, 121 Tuinenga, P W., 128, 133 Turing, A., 72, 73, 90 Tyson, J J., 53 Wagner, A., 221 Wagner, G P., 166 Waldrop M M., 254 Walz, D., 116 Watts, D., 163 Watts, D J., 213 Weaver, W., 2, 191 Weber, B H., 325 Welch, G R., 284, 285 Wells, H G., 256 Welz, G., 27 Weng, G., 221 White, J C., 116, 134 Wiener, H., 1, 211 Wieschaus, E., 79 Winfree, A T., 89 Witten, T M., 239, 243, 245, 246, 252, 253 Wolfram, S., 257 Wolpert, L., 70 Wright, W F., 192, 230 Wyatt, J L., 115, 128, 134 Ulam, S M., 257 Ulanowicz, R E., 307, 308, 313, 316, 320, 322, 323, 324, 325, 326, 327 Yamamoto, M., 76 Yomo, T., 60, 62, 64, 91 Yook, S H., 226 Yost, H J., 76 Van Obberghen-Schilling, E., 73 Varela, F J., 112, 146, 311 V´azquez, A., 176, 178 Vichniac, G Y., 257 Vogt, K., 27 von Dassow, G., 90 von Neumann, J., 257 Waddington, C H., 83, 286 Wagensberg, J., 322 Zamfirescu, C M., 27 Zeeman, E C., 66, 90 Zengl, A P., 221 Zhang, G., 43 Zhu, H., 37 Zhu, H Y., 43 Zimmermann, H J., 132 Zorach, A C., 320, 322 Zuse, K., 257 SUBJECT INDEX A/D index, 213–215, 217 Absolute gravity, 271 Accessible connectedness, 219–220 Activators, 55 Acyclic complexity, Adjacency matrix, 195–196 leading eigenvalue of, 7–16 Adjacent vertices, 195 Adjusted average distance, 219 Admittance matrix, 129 Agents, 250–251 Algorithmic information, 191 Algorithms, 108 AMC (average mutual constraint), 320–321 Analog models of network thermodynamics, 121 Arcs, 194 Armchair nanotubes, 39 Ascendency, 321 Assortativeness of networks, 172 Asynchronous cell movement, 264–266 Atom environments, local, 25–29 Atomic complexity index, 23 Augmented valence complexity index, 16–20, 30 Autocatalysis, 73 non–mechanical behavior and, 311–316 Autopoiesis, 146 Autopoietic unity, 112 Autoregulatory transcription factor network model, Keller, 55–59 Average degree, 158 Average edge complexity, 206 Average graph distance, 198 Average mutual constraint (AMC), 320–321 Average path length, 159–161 Average vertex degree, 196 Axis formation left–right symmetry and, 71–72 Meinhardt’s models for, 72–76 B index, 215–218 Basin of attraction, 54 Biochemical networks, modeling, 289–297 Biochemical state of cells, 52 Biochemical systems, complex, cellular automata models of, 237–298 Biological development and evolution, complex chemical systems in, 49–51 337 338 Biological networks, complexity estimates of, 221–230 Biology, relational systems theory in, 141–144 Biosystems, complex, modeling emergence in, 257–274 Blastulae, 51 Bond graphs, 118 Boolean network, random (RBN), 181–183 Boron, 36 Boundary conditions, zero–flux, 86 Brain, 101 Branching, complexity and, 4–7 degree of, 6, 11 molecular, 5, 6–7 Breaking rules, 269 Canalizing selection, 83 Capacitance, electrical, 124–125 Capacitor, 122 Carbon, 36 Carbon nanotubes, see Nanotubes Causality, 99, 316–317 Cayley–Hamilton theorem, Cell differentiation, dependence of, 59–64 Cell division cycle, 52 Cell movement, 262–267 Cell movement rules, 267–273 Cell rotation, 271, 273 Cell shape, 259 Cell theory, 146 Cell type diversification, multistability in, 53–55 Cell types, 261–262 Cells, 155, 258–262 Cellular automata, 138, 257–262 Cellular automata models collection of data in, 273–274 of complex biochemical systems, 237–298 examples of, 274–297 biochemical networks, 289–297 Subject Index Cellular automata models (cont.) chreode theory of diffusion in water, 283–289 diffusion in water, 280–283 molecular bond interactions, 277–280 water structure, 275–277 Chaotic systems, 115 Chemical dynamics, insect segmentation and, 80–83 Chemical oscillations, somitogenesis and, 65–66 Chemical reaction networks, simulation of, 134 Chemistry models in, 246–248 relational systems theory in, 141–144 Chreode theory of diffusion in water, 283–289 Chreodes, 280–281 Church–Turing thesis, 108 Circular reasoning, Circularity of context dependence, 97–98 Clustering, hierarchical, in contact maps, 166–169 Clustering coefficient, 161–162, 196–197 second, 197 Combinatorial complexity, 191 Community effect, 59–60 Comparability inequalities, Muirhead, 28 Compartmental systems, mass transport in, 134 Complete graphs, 194 Complex chemical systems in biological development and evolution, 49–51 Complex reality, 147 Complexity, 2, 90, 144 acyclic, attempts to simplify, 97–148 branching and, 4–7 of carbon nanotubes, 36–43 combinatorial, 191 Subject Index Complexity (cont.) of complexity concept, 3–4 compositional, 191 defining, 248–257 of ecodynamics, 303–327 general principles of, 248–257 global, 24 molecular, network, see Network complexity of smaller fullerenes, 20–24 of smaller molecules, 7–16 Complexity concept, complexity of, 3–4 Complexity estimates of biological and ecological networks, 221–230 Complexity index atomic, 23 augmented valence, 16–20, 30 molecular, 23 Complexity index B, 215–218 Complexity measures, combined, 213–218 desirable properties for, Complexity theory, 114, 192 emergence in, 139–148 Complexity vectors, 35 Components, 4, 159 functional, 106 graph, 194 Compositional complexity, 191 Connected graph, 194 Connectedness, 196 accessible, 219–220 Connectivity, extended, 17, 197 overall (OC), 210–211 Constitutive laws for physical systems, 122–123 Constraint(s) incorporated, measuring effects of, 306–307 new, in ecosystems, 324–327 quantifying, in ecosystems, 318–324 Contact graphs, protein structure and, 164–169 339 Contact maps, hierarchical clustering in, 166–169 Context dependence circularity of, 97–98 self reference and, 102–103 Contingency, ecosystems and, 307–311 Correlation profiles, 172–175 Crude symmetry (CS), 33, 34 CS (crude symmetry), 33, 34 Curie’s principle, 142–143 Cycle, 194 Cyclic graphs, 194 DDSs (distance degree sequences), 20–24, 198 Degree, 157 of branching, 6, 11 Degree distribution, 158 Dependency networks, 253 Determination, 51 Deterministic cell movement rules, 266–267 Developmental mechanisms, evolution of, 76–89 Developmental robustness, evolution of, 83–89 Differential gene expression, 49 Differentiation, 52 Diffusion in water, 280–283 Directed graphs, 127, 194, 253 Disconnected graph, 194 Distance, 198 Distance degree distribution, 198 Distance degree sequences (DDSs), 20–24, 198 Distance in–degrees, 200 Distance magnitude distribution, 198 Distance matrix, 198 Distance out–degrees, 200 Dynamics, 125 Newtonian, 112–114 Ecodynamics, 303 complexity of, 303–327 340 Ecological networks, complexity estimates of, 221–230 Ecosystems contingency and, 307–311 new constraints in, 324–327 quantifying constraints in, 318–324 Edges, 157, 193 Electric circuits, network thermodynamics and, 119–120 Electrical capacitance, 124–125 Embryo pattern formation, reaction– diffusion mechanisms and, 70–76 Embryogenesis, 49 Emergence, 256 in complexity theory, 139–148 modeling, in complex biosystems, 257–274 Entailment, 110 Entropy of information, 202 Shannon, 204 Epigenetic inheritance, 54 Epigenetic multistability, 55–59 Epigenetic system, 84 Euler’s theorem, 194 Extended connectivity, 17, 197 External world, human mind and, 99–100 Fick’s law, 123 Food webs, 226–230 Formal description of networks, 126–128 Formal system, 99 Fragmentability, 108 Fullerenes smaller, complexity of, 20–24 symmetry and, 29–34 Functional components, 106 Gene duplication, 175 Gene expression, differential, 49 Gene networks, 180–187 Genericity, 107 Giant component, 159 Global complexity, 24 Subject Index Global edge complexity, 206 Gordon–Scantleburry index, 208 Graph center, 198, 200 Graph complexity, Graph components, 194 Graph diameter, 198 Graph distances, 198–200 Graph theory, 193 basic notions in, 193–194 Graphitic cones, 43 Graphs, 157–158, 253 bond, 118 complete, 194 contact, protein structure and, 164–169 directed, 127 linear, 126 networks as, 193–201 random, 158 simple, 194 weighted, 201 Gravity, 113 Hasse diagrams, 10 Heaviside function, 86 Helicity, 39 of nanotubes, 38–43 Hierarchical clustering in contact maps, 166–169 Hierarchy, 251–254 Hill function, 85 Hopf instability, 79 Human mind, external world and, 99–100 Hydrophobic effect, 284–285 In–adjacency, 196 In–center, 200 In–component, 200 In–degree, 157, 196 Incidence matrix, 127 Incorporated constraints, measuring effects of, 306–307 Induction, mesoderm, 70 Subject Index Inductor, 122 Inferences, 100 Information, 104–105 algorithmic, 191 entropy of, 202 topological, 191 Information content, Information indices, 192 Insect segmentation, 77–80 chemical dynamics and, 80–83 Interactions, 242–243 Isologous diversification, 60 Isologous diversification model, Kaneko–Yomo, 59–64 Joining parameter, 267, 268 Kaneko–Yomo isologous diversification model, 59–64 Keller autoregulatory transcription factor network model, 55–59 Kirchhoff’s effort law, 128 Kirchhoff’s flow law, 127–128 Kirchhoff’s laws, 119 Knowledge, quest for, 101 Law of conservation of energy, 114 Law of inertia, 113 Leading eigenvalue of adjacency matrix, 7–16 Left–right symmetry, axis formation and, 71–72 Lewis–Monk model of somitogenesis oscillator, 66–69 Linear graphs, 126 Linear multiports, 130–133 Linear resistive networks, 128–130 Link deletion, 178 Link–density, 322 Links, 157, 193 Local atom environments, 25–29 Loop, 193, 196 341 Machines, organisms versus, 108–112 MAPK cascade signaling pathway, 290–297 Mass transport in compartmental systems, 134 Mathematics of science, 117–118 Mechanisms, relational models of, 112 Mechanistic theories, 115 Meinhardt’s models for axis formation, 72–76 Memristor, 123 Mesoderm induction, 70 Metabolism–Repair [M, R] system, 104 Mind, human, external world and, 99–100 Model, 99 Modeling process, 238–244 Models, 238–239, 244–246 in chemistry and molecular biology, 246–248 simulations versus, 244–246 successful, 240–241 Molecular biology, models in, 246–248 Molecular bond interactions, 277–280 Molecular branching, 5, 6–7 Molecular complexity, Molecular complexity index, 23, 192 Molecular dynamics approach, 246–248 Monocilia, 76 Monte Carlo calculations, 246–248 Moore neighborhood, 262, 263 Morgan algorithm, 17 Morphogens, 70 Movement probability, 267 [M, R] Metabolism–Repair system, 104 MRDH (mutual repression by dimer and heterodimer) network, 56–58 Muirhead comparability inequalities, 28 Multigraph, 194 Multiports, 130 linear, 130–133 Multistability in cell type diversification, 53–55 epigenetic, 55–59 342 Mutations, 175 Mutual repression by dimer and heterodimer (MRDH) network, 56–58 Nanotube diameter, 43 Nanotubes complexity of, 36–43 helicity of, 38–43 Neighborhoods, 262–264 Network complexity measuring, 202–213 quantitative measures of, 191–232 Network thermodynamics, 115–116, 135, 138, 144 analog models of, 121 electric circuits and, 119–120 structure of, 118–133 Networks, 103, 155, 221 assortativeness of, 172 biochemical, modeling, 289–297 characterizing, 120–121 chemical reaction, simulation of, 134 dependency, 253 formal description of, 126–128 gene, 180–187 as graphs, 193–201 linear resistive, 128–130 non–linear, simulation on SPICE, 133–138 of protein complexes, 222–226 protein interaction, 169–170 relational, 138–148 topology of, 120, 126 Newtonian dynamics, 112–114 Nieuwkoop center, 74 Nodes, 157, 193 Non–equilibrium thermodynamics, 141 Non–linear networks, simulation on SPICE, 133–138 Non–mechanical behavior, autocatalysis and, 311–316 Normalized edge complexity, 206 Subject Index Objectivity, 100 science and, 100–102 Observables, 242 OC (overall connectivity), 210–211 Octane, isomers of, 8, 10, 12–14 Ohm’s law, 123 Onsager/Prigogine representation, 135 Onsager reciprocal relations (ORR), 131, 136–138 Organisms, machines versus, 108–112 ORR (Onsager reciprocal relations), 131, 136–138 Oscillatory mechanisms, 84 Out–adjacency, 196 Out–center, 200 Out–component, 200 Out–degree, 158, 195 Overall connectivity (OC), 210–211 Path, 194, 198 Path graph, 194 Path matrix, Pattern, Pattern formation, embryo, reaction– diffusion mechanisms and, 70–76 Physical systems, constitutive laws for, 122–123 Physiology, 105 Platt index, 207 Poiseuille’s law, 124 Poisson distribution, 158 Probabilistic cell movement rules, 266–267 Propensity, 310 Protein complexes, networks of, 222–226 Protein folding maps, small–world structure of, 165 Protein interaction networks, 169–170 Protein molecules, 155–156 Protein structure, 165 contact graphs and, 164–169 Proteins, 164 Subject Index Proteome growth, rules of, 176 Proteome model, 175–180 Quasi power theorem, 137 Quest for knowledge, 101 Random Boolean network (RBN), 181–183 Random graphs, 158 RBM (random Boolean network), 181–183 Reaction–diffusion mechanisms, embryo pattern formation and, 70–76 Reaction–diffusion systems, 71 Reductionism, 106, 117–118 relational systems theory versus, 107–108 Relational block diagrams, 103–104 Relational models of mechanisms, 112 Relational networks, 138–148 Relational systems theory, 103 in chemistry and biology, 141–144 reductionism versus, 107–108 Relative gravity, 269–271, 272 Repressors, 55 Resistive networks, linear, 128–130 Resistor, 122 Reversibility, 325 Riemann zeta function, 186 Robustness, developmental, evolution of, 83–89 SC (subgraph count), 207–209 SC (symmetry corrected), 31 Schlegel diagrams, 20 Science mathematics of, 117–118 objectivity and, 100–102 Scientific model, 100–101 Second cluster coefficient, 197 Segmentation, 65 insect, see Insect segmentation Self–organization, 254–256 Self reference, 106 343 Self reference (cont.) context dependence and, 102–103 Sensory physiology, 99 Shannon entropy, 204 Shannon theory, 203 Silicon, 36 Simple graphs, 194 Simulations, models versus, 244–246 Small–world effect, 162–164 Small–world structure of protein folding maps, 165 Somitogenesis, 65 chemical oscillations and, 65–66 Somitogenesis oscillator, Lewis–Monk model of, 66–69 Spanning tree, 194 Spemann–Mangold organizer, 71–72, 74 SPICE, non–linear networks simulation on, 133–138 Star graph, 194 States of systems, 241–242 Strongly connected component, 200 Subgraph, 193 Subgraph count (SC), 207–209 Sulfur, 36 Symmetry fullerenes and, 29–34 left–right, axis formation and, 71–72 Symmetry corrected (SC), 31 Symmetry factor, 31 Synchronous cell movement, 264–266 Synthesis, 109 System overhead, 322 Systems, 241 states of, 241–242 TC (topological complexity), 211 Tellegen’s theorem, 120, 137 Thermodynamics, 114 network, see Network thermodynamics non–equilibrium, 141 Time lag, 90 TO (topological overlap), 166 Topological complexity (TC), 211 344 Topological indices, 35 Topological information, 191 Topological overlap (TO), 166 Topological reasoning, 116 Topology of networks, 120, 126 vector calculus and, 118 Total adjacency, 195, 205–206 Total walk count (TWC), 211–213 Transcription factors, 55, 180–181 Trees, 194 Tube, 226 Turing instability, 71, 79 TWC (total walk count), 211–213 Subject Index Vertex degree distribution, 195, 203 Vertex distance, 198 Vertex eccentricity, 198 Vertices, 157, 193 adjacent, 195 von Neumann neighborhood, 262, 263 extended, 264 Undirected graph, 194 Unistors, 132 Walk, 194 Walk count, 15 Walk length, 194 Water structure, 275–277 Weighted adjacency matrix, 201 Weighted graphs, 201 World, external, human mind and, 99–100 Vector calculus, topology and, 118 Vegetal pole organizer, 73 Vertex accessibility, 219 Vertex degree, 195 Zero–flux boundary conditions, 86 Zeta function, Riemann, 186 Zigzag nanotubes, 39, 40–42 ... mathematical biology, which is more and more dominated by systems biology and bioinformatics This has also changed the approaches used to quantify complexity in biology and ecology In addition to information... matrix as an index of molecular branching [37] Hence, are we in this way using branching indices for measuring complexity and in the case of acyclic graphs equating branching with complexity? ... of complexity can be utilized in a variety of disciplines is made explicit The specific disciplines that we embrace herein are chemistry, biochemistry, biology, and ecology Chapter 1, “On the Complexity

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  • Cover Page

  • Title Page

  • ISBN 0387232648

  • CONTRIBUTORS

  • PREFACE

  • CONTENTS

    • 1 ON THE COMPLEXITY OF FULLERENES AND NANOTUBES

    • 2 COMPLEXITY AND SELF-ORGANIZATION IN BIOLOGICAL DEVELOPMENT AND EVOLUTION

    • 3 THE CIRCLE THAT NEVER ENDS: CAN COMPLEXITY BE MADE SIMPLE?

    • 4 GRAPHS AS MODELS OF LARGE-SCALE BIOCHEMICAL ORGANIZATION

    • 5 QUANTITATIVE MEASURES OF NETWORK COMPLEXITY

    • 6 CELLULAR AUTOMATA MODELS OF COMPLEX BIOCHEMICAL SYSTEMS

    • 7 THE COMPLEX NATURE OF ECODYNAMICS

  • 1 ON THE COMPLEXITY OF FULLERENES AND NANOTUBES

    • 1. Introduction

    • 2. On the Complexity of the Complexity Concept

    • 3. Complexity and Branching

    • 4. Complexity of Smaller Molecules

    • 5. Augmented Valence as a Complexity Index

    • 6. Complexity of Smaller Fullerenes

    • 7. Comparison of Local Atomic Environments

    • 8. The Role of Symmetry

    • 9. Concluding Remarks on the Complexity of Fullerenes

    • 10. On the Complexity of Carbon Nanotubes

      • 10.1. Introductory remarks

      • 10.2. Helicity of nanotubes

  • 2 COMPLEXITY AND SELF-ORGANIZATION IN BIOLOGICAL DEVELOPMENT AND EVOLUTION

    • 1. Introduction: Complex Chemical Systems in Biological Development and Evolution

    • 2. Dynamic Multistability and Cell Differentiation

      • 2.1. Cell states and dynamics

      • 2.2. Epigenetic multistability: the Keller autoregulatory transcription factor network model

      • 2.3. Dependence of differentiation on cell-cell interaction: the Kaneko-Yomo “isologous diversification” model

    • 3. Biochemical Oscillations and Segmentation

      • 3.1. Oscillatory dynamics and somitogenesis

      • 3.2. The Lewis model of the somitogenesis oscillator

    • 4. Reaction-Diffusion Mechanisms and Embryonic Pattern Formation

      • 4.1. Reaction-diffusion systems

      • 4.2. Axis formation and left-right asymmetry

      • 4.3. Meinhardt’s models for axis formation and symmetry breaking

    • 5. Evolution of Developmental Mechanisms

      • 5.1. Segmentation in insects

      • 5.2. Chemical dynamics and the evolution of insect segmentation

      • 5.3. Evolution of developmental robustness

    • 6. Conclusions

  • 3 THE CIRCLE THAT NEVER ENDS: CAN COMPLEXITY BE MADE SIMPLE?

    • 1. Introduction: The Nature of the Problem and Why it Has No Clear Solution

      • 1.1. The human mind and the external world

      • 1.2. Science and the myth of objectivity

      • 1.3. Context dependence and self reference

    • 2. An Introduction to Relational Systems Theory

      • 2.1. Relational block diagrams

      • 2.2. Information as an interrogative. The answer to “why?”

      • 2.3. Functional components and their central role in complex systems

      • 2.4. The answer to “why is the whole more than the sum of its parts?”

      • 2.5. Reductionism and relational systems theory compared

      • 2.6. The functional component is not computable

      • 2.7. An example: the [M,R] system and the organism/machine distinction

      • 2.8. Relational models of mechanisms

      • 2.9. Newtonian dynamics is not unique; there are alternatives that yield equivalent results

      • 2.10. Topology, thermodynamics and relational modeling

      • 2.11. The mathematics of science or is all mathematics scientific?

      • 2.12. The parallels between vector calculus and topology

    • 3. The Structure of Network Thermodynamics as Formalism

      • 3.1. Network thermodynamic modeling is analogous to modeling electric circuits

      • 3.2. The network thermodynamic model of a system

      • 3.3. Characterizing the networks using an abstraction of the network elements

      • 3.4. The nature of the analog models that constitute network thermodynamics

      • 3.5. The constitutive laws for all physical systems are analogous to the constitutive laws for electrical networks or can be constructed as the models for electronic elements

      • 3.6. The resistance as a general systems element

      • 3.7. The capacitance as a general systems element

      • 3.8. The topology of a network

      • 3.9. The formal description of a network

      • 3.10. The formal solution of a linear resistive network

      • 3.11. The use of multiports for coupled processes: the entry to biological applications

      • 3.12. Linear multiports are based on non-equilibrium thermodynamics

    • 4. Simulation of Non-Linear Networks on Spice

      • 4.1. Simulation of chemical reaction networks

      • 4.2. Simulation of mass transport in compartamental systems and bulk flow

      • 4.3. Network thermodynamics contributions to theory: some fundamentals

      • 4.4. The canonical representation of linear non-equilibrium systems, the metric structure of thermodynamics, and the energetic analysis of coupled systems

      • 4.5. Tellegen’s theorem and the onsager reciprocal relations (ORR)

    • 5. Relational Networks and Beyond

      • 5.1. A message from network theory

      • 5.2. An “emergent” property of the 2-port current divider

      • 5.3. The use of relational systems theory in chemistry and biology: past, present, and future

      • 5.4. Conclusion: there is no conclusion

  • 4 GRAPHS AS MODELS OF LARGE-SCALE BIOCHEMICAL ORGANIZATION

    • 1. Introduction

    • 2. Basic Properties of Random Graphs

      • 2.1. Degree distribution

      • 2.2. Components

      • 2.3. Average path length

      • 2.4. Clustering

      • 2.5. Small-worlds

    • 3. Protein Structure and Contact Graphs

      • 3.1. Proteins are small worlds

      • 3.2. Hierarchical clustering in contact maps

    • 4. Protein Interaction Networks

      • 4.1. Assortativeness and correlations

      • 4.2. Correlation profiles

      • 4.3. Proteome model

    • 5. Gene Networks

    • 6. Overview

  • 5 QUANTITATIVE MEASURES OF NETWORK COMPLEXITY

    • 1. Some History

    • 2. Networks as Graphs

      • 2.1. Basic notions in graph theory [36-38]

      • 2.2. Adjacency matrix and related graph descriptors

      • 2.3. Clustering coefficient and extended connectivity

      • 2.4. Graph distances

      • 2.5. Weighted graphs

    • 3. How to Measure Network Complexity

      • 3.1. Careful with symmetry!

      • 3.2. Can Shannon’s information content measure topological complexity?

      • 3.3. Global, average, and normalized complexity

      • 3.4. The subgraph count, SC, and its components

      • 3.5. Overall connectivity, OC

      • 3.6. The total walk count, TWC

    • 4. Combined Complexity Measures Based on the Graph Adjacency and Distance

      • 4.1. The A/D index

      • 4.2. The complexity index B

    • 5. Vertex Accessibility and Complexity of Directed Graphs

    • 6. Complexity Estimates of Biological and Ecological Networks

      • 6.1. Networks of Protein Complexes

      • 6.2. Food webs

    • 7. Overview

  • 6 CELLULAR AUTOMATA MODELS OF COMPLEX BIOCHEMICAL SYSTEMS

    • 1. Reality, Systems, and Models

      • 1.1. Introduction

      • 1.2. The “what” of modeling and simulation

      • 1.3. Back to models

      • 1.4. Models in chemistry and molecular biology

    • 2. General Principles of Complexity

      • 2.1. Defining complexity: complicated vs. complex

      • 2.2. Defining complexity: agents, hierarchy, self-organization, emergence, and dissolvence

    • 3. Modeling Emergence in Complex Biosystems

      • 3.1. Cellular automata

      • 3.2. The general structure

      • 3.3. Cell movement

      • 3.4. Movement (transition) rules

      • 3.5. Collection of data

    • 4. Examples of Cellular Automata Models

      • 4.1. Introduction

      • 4.2. Water structure

      • 4.3. Cellular automata models of molecular bond interactions

      • 4.4. Diffusion in water

      • 4.5. Chreode theory of diffusion in water

      • 4.6. Modeling biochemical networks

    • 5. General Summary

  • 7 THE COMPLEX NATURE OF ECODYNAMICS

    • 1. Introduction

    • 2. Measuring the Effects of Incorporated Constraints

    • 3. Ecosystems and Contingency

    • 4. Autocatalysis and Non-Mechanical Behavior

    • 5. Causality Reconsidered

    • 6. Quantifying Constraint in Ecosystems

    • 7. New Constraints to Help Focus a New Perspective

  • AUTHOR INDEX

  • SUBJECT INDEX

    • A

    • B

    • C

    • D

    • E

    • F

    • G

    • H

    • I

    • J,K

    • L

    • M

    • N,O

    • P

    • Q,R,S

    • T

    • U,V,W,Z

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